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J o u r n a l of the American Chemical Society
research group for their contributions, especially to T. AIbright, P. J. Hay, D. L. Thorn, and M.-H. Whangbo. We also benefited from conversations with L. S. Bartell and the comments of a referee. The work a t Cornell was supported by the National Science Foundation. We thank Professor A. Veillard from the University of Strasbourg and Dr. P. Bagus from the IBM Research Laboratories, San JosC, Calif., for the computer output of their SCF calculations on ferrocene. W e are also grateful to L. Zoller for his help in the computational work. The work at ETH was supported by the Swiss National Science Foundation (No. 2.171-0.74).
Appendix The Wolfsberg-Helmholz E H calculations with self-consistent charge and configuration (SCCC) were performed on Fe(C5H5)2 using a model with D5h symmetry and the following bond distances: d(C-C) = 1.42 A, d(C-H) = 1.1 A, d(Fecenter of C5H5) = 1.65 A. The multiexponential radial functions of Richardson25were used for 3d, 4s, and 4p orbitals of Fe. Double {orbitals of Sakai and AnnoZbwere used for 2s(C) and 2p(C) with H ~ Q ~ ( C =) -21.4 eV and H2p2p(C) = - 11.4 eV. For hydrogen { = 1.2 and H l s l s = -13.6 eV were chosen. The S C C C iterations for the Fe Hi,'s were performed with the parameter set of Basch et al.27 In Tables I1 and V only one representative of degenerate MOs is listed. Also, only coefficients for one selected carbon (CI) and hydrogen ( H I ) are given. Coefficients for the remaining representatives of degenerate MOs and for the remaining carbon and hydrogen atoms are then determined by the D 5 h symmetry of the ferrocene molecule. The notation x for 2p,(C) and (r for 2p, and 2p,.(C) refers to the planar ligand C5H5. References and Notes (1) (a) ETH; (b) Cornell University.
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(2) (a) M. Wolfsberg and L. Helmholz, J. Chem. Phys., 20, 837 (1952); (b)L. C. Cusachs and B. B. Cusachs, J. fhys. Chem., 71, 1060 (1967). (3) C.J. Ballhausen and H. B. Gray, Inorg. Chem., 1, 111 (1962). (4) Photoelectronspectra of transition metal compounds and their !heoretical interpretation in terms of SCF calculations make it sometimes necessary to postulate high-lying bonding orbitals mainly ligand in character as well as the corresponding low-lying antibonding orbitals mainly metal in character. These peculiar phenomena have been discussed in terms of differences between interelectronic repulsion integrals of ligand orbitals and metal orbitals and in terms of the concomitant orbital relaxation effects. They may well turn out to require violations of rule 3. For discussion see c. K. Jqrgensen, Chimia, 28, 6 (1974): J. Demuynck, A. Veillard, and U. Wahlgren, J. Am. Chem. SOC.,95, 5563 (1973); and ref 12. (5) J. H. Schachtschneider, R. Prins. and P. Ros, Inorg. Chim. Acta, 1, 462 (1967). (6) (a) A. T. Armstrong, D. G. Carroll, and S. P. McGlynn, J. Chem. fhys., 47, 1104 (1967); (b) D. G. Carroll and S. P. McGlynn, lnorg. Chem., 7, 1285 (1968). (7) F. A. Cotton, C. 8. Harris, and J. J. Wise, Inorg. Chem., 6, 909 (1967). (8) S.E. Anderson, Jr., and R. S. Drago, Inorg. Chem., 11, 1564 (1972). (9) K. Gustav, 2.Chem., 15, 39 (1975). (IO) M.-M. Coutiere, J. Demuynck, and A. Veillard, Theor. Chim. Acta, 27, 281 (1972). (11) P. S. Bagus, U. I. Walgren, and J. Almlof, J. Chem. Phys., 64, 2324 (1976). (12) The effect has been clearly noted by K. G. Caulton and R. F. Fenske, Inorg. Chem., 7, 1273 (1968). (13) M. B. Hall, I. H. Hillier, J. A. Connor. M. F. Guest, and D. R. Lloyd, Mol. fbys., 30,839 (1975). J. A. Connor, L. M. R. Derrick, M. B. Hall, I. H. Hillier, M. F. Guest, B. R. Higginson, and D. R. Lloyd, Mol. Phys., 28, 1193 (1974). E. J. Baerends and P. Ros, Mol. Phys., 30, 1735 (1975). (a) J. Demuynck and A. Veillard, Theor. Chim. Acta, 28, 241 (1973); (b) I. H. Hillier and V. R. Saunders, Chem. Commun., 642 (1971). 0. R. Armstrong and R. H. Findlay, Inorg. Chim. Acta, 21, 55 (1977). M. F. Guest, I. H. Hillier, B. R. Higginson, and D. R . Lloyd, Mol. fhys., 29, 113 (19751. (19) P. E.'Cadeand W. M. Huo, J. Chem. Phys., 47, 614, 649 (1967). (20) L. C. Snyder and H. Basch, "Molecular Wave Functions and Properties," Wiley-lnterscience, New York, N.Y., 1972. (21) M.-H. Whangbo and R. Hoffmann, J. Chem. Phys., in press. (22) C. J. Marsden and L. S. Bartell, lnorg. Chem., 15, 2713 (1976). (23) (a) A. B. Anderson, J. Am. Chem. SOC.,99, 696 (1977); (b) J. Chem. Phys., 65, 1729 (1976); (c)!o be published. (24) C. J. Ballhausen and H. B. Gray in "Coordination Chemistry", ACS Monogr., No. 168, 32 (1971). (25) J. W. Richardson, W. C. Nieuwpoort, P. R. Powell, and W. F. Edgell, J. Chem. fhys., 36, 1057 (1962). (26) Y. Sakai and T. Anno, J. Chem. Phys., 60, 620 (1974). (27) H. Basch, A. Viste, and H. B. Gray, J. Chem. Phys., 44, 10 (1966).
Interaction between Matrix Isolated Nickel Difluoride and Carbon Monoxide. An ab Initio Molecular Orbital Study S. Besnainou*la and J. L. WhittentIb Contribution from the Centre de MCcanique Ondulatoire AppliquCe, 75019 Paris, France, and the Centre Europeen de Calcul Atomique et Mo/eculaire, Universite de Paris XI,Orsay, France. Receiced July 1 I , 1977
Abstract: The interaction between Ar matrix isolated NiF2 with C O is studied by an a b initio molecular orbital method. First the electronic structures of NiF2, CO, and CO+ are investigated using a Gaussian lobe basis set. The NiFz bond angle is found to be 162' in good agreement with the experimental determination; also the N i F bond has a slightly covalent character. The electronic structure of NiFZCO is then determined and the emphasis is put on the modification of the CO bond from free CO to NiF2CO. It is shown that the presence of the dipositive nickel atom induces a polarization of the charges leading to a strengthening of the bond. This is consistent with the experimental observation of a 70-cm-' shift of the CO frequency toward higher wavenumbers. Comparison of the dipole moment of the "complex" with the component dipoles shows equally a polarization effect on the CO bond.
I. Introduction Coordinately unsaturated metal dihalides and diatomic molecules isolated in rare gas matrices can interact as has been Permanent address: Department of Chemistry, State University of New York at Stony Brook, Stony Brook, N.Y.11794.
0002-7863/78/1500-3692$01.00/0
shown bv infrared sDectrosco~v.12 If the effect of the matrix on each member of the associated species is known from a separate it is then possible to determine what modifications of the spectra are due to the intermolecular forces. The goal of the present work is to study the interaction of 1
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0 1978 American Chemical Society
Besnainou, Whitten / Interaction between Nickel Difluoride and Carbon Monoxide Table I. C O and CO+ S C F Orbital and Total Energies for ‘ Z + and *Z+ Ground Statesa
la 2a 3a 4a T
5a Total energy
CO. au
CO+. a u
-20.7195 - 1 1.4466 -1.5866 -0.8052 -0.6689 -0.5767 - 1 12.6043
-21.21 30 - 12.0451 -2.021 3 -1.1934 -1.0816 -1.1415 -1 12.0571
Calculations were performed a t the experimental equilibrium internuclear distance of 2.132 au. 1 au (energy) = 27.21 eV; 1 au (distance) = 0.5292 A. a
Table 11. C O and CO+ S C F and C I Energy as a Function of Internuclear Distancea
Reo
Eco
ECO+
1.932
-112.5548
2.132
- 1 12.6043 (-1 12.7175) - 1 12.6069 (-112.7266) - 1 12.6000 (-112.7256)
-1 12.01 97 (-1 12.1349) -1 12.0571 (-1 12.1971) -112.0555 (-1 12.2063) -1 12.0466 (-1 12.2040)
2.232 2.332
a CI values are in parentheses. Energies and distances are in atomic unit.
NiF2 and CO by means of molecular orbital theory using an a b initio self-consistent field (SCF) approach. The experimental results2 show that both the spectra of NiF2 and CO are modified in an argon matrix. In particular, the CO stretching frequency is shifted toward higher wavenumbers by about 70 cm-’ which makes it closer to the frequency of free CO+. The effect of the matrix on CO alone is known to be a shift of a few w a v e n ~ m b e r sIn . ~ this work, the electronic structures of CO+, CO, NiF2, and NiF2CO are studied, with emphasis being placed on modifications of the CO bond in going from CO to NiF2CO. 11. Methods
The calculations are of a restricted S C F type using a contracted Gaussian lobe function basis. Orbitals for carbon, oxygen, and fluorine have already been r e p ~ r t e dand , ~ of these, the five-term p orbitals a r e split into two groups, (1,2,3) and (4,5). Although this splitting does not affect the energy of the atoms, it could play a part in molecular binding. Qualitatively, nickel fluoride is assumed to have an electronic structure similar to Ni2+ (F-)2. The fluorine basis was taken to be that of the negative ion.6a For Ni2+, the Gaussian lobe basis set was deduced from the contracted 9s, 5p, 3d Gaussian basis set by Roos et a1.,6baugmented by another s component and p component a s given by Basch et al.738 Summarizing, the basis groups (contractions) for nickel are as follows: s, (1,2,3,4,5) (6,7), ( 8 3 ) (10); p, (1,2,3) (4,5) (6); d, ( 1 J ) (3). The NiZ+ energy of -1499.4044 au found in ref 6b is lowered to -1500.31 13 au by adding the two s and p components. For comparison, Clementi’s double {basis set leads to an energy of -1506.3702 au, and the principal source of error in the present basis lies in the inner shell orbitals. Configuration interaction (CI) studies employed the scheme due to Whitten and H a ~ k r n e y e r . ~ 111. Results and Discussion
Carbon Monoxide. Carbon monoxide and CO+ are studied, and energies are computed a t various internuclear distances. Effects of a limited C I have also been taken into consideration.
3693
’&able 111. C O and CO+ Minimum Energy, Equilibrium Internuclear Distance, and Force Constant
CO CO+
Calcd S C F Calcd C I Exptl Calcd S C F Calcd C I Exptl
Rco. au
E . au
k . mdvn/A
2.20 2.27 2.132” 2.16 2.26 2.1074a
-112.6073b -112.7275 -113.377‘ -1 12.0577 -1 12.2068 -112.862Id
16.10 15.80 18.55d 16.29 17.88 19.22d
a Reference 11. The present value obtained with a [30/10] basis should be compared to the following: (1) the Hartree-Fock limit -1 12.821 1 au (C. Hollister and 0. Sinanoglu, J . A m . Chem. SOC., 88, 13 (1966)); (2) -112.6762 au, a [42,20] calculation made at R = 2.132 au by H . Basch, M . B. Robin and N . A. Kuebler, J . Chem. Phys., 47, 1201 (1967), and (3) -112,550 au, a [24/8] calculation made at R = 2.175 au by J. Demuynk and A. Veillard, Theor. Chim. Acta, 28,241 (1973). B. J. Ransil, Rec. Mod. Phys., 32,239 (1960). Calculated from experimental data: 2170 cm-l ( C O stretching), 2214 cm-’ (CO+ stretching), and 14.01 eV (ionization potential), as given by G. Herzberg, “Molecular Spectra and Molecular Structure’’, Vol. I, Van Nostrand, Princeton, N.J., 1950.
Table I shows the calculated SCF eigenvalues of C O a t the experimental equilibrium internuclear distance for the Z+ state, and these agree fairly well with results already published.I0 Table I also gives values for the 2Z+ state of CO+ (at the same internuclear distance as in CO). Orbital energies are lowered significantly on the loss of one electron, and the 5 a and P orbitals change order. This is in agreement with results of Sahni et aI.,l1 who report an unrestricted Hartree-Fock treatment. Table I1 gives the energies of C O and CO+ as a function of the internuclear distance. In the C I calculations using S C F MOs, two orbitals were kept in an invariant core. For the IZ+state of CO, 11 orbitals outside the core were selected for the generation of configurations from 6 parents (see ref 9). For the 2Z+state of CO+, 9 such orbitals were included. Finally, 158 determinants were generated for the IZ+state and 11 1 for the 2Z+ state. In both cases the energy is lowered by a little more than 0.1 au from the SCF value. The vertical ionization energy at R = 2.132 au goes from 14.9 eV at the S C F level to 14.2 eV on CI, the observed value being 14.01 eV.Io The dipole moment goes from -0.256 (SCF) to -0.076 au (CI), the observed value being -0.047 au (0.12 D), the negative sign indicating the orientation C- O+. The equilibrium bond length, minimal energy, and force constants have been calculated using a polynomial fit to the energy curve for the SCF and C I calculations; results a r e tabulated in Table 111. The observed bond length decrease and force constant increase in going from C O to CO+ are reflected qualitatively by both the SCF and C I calculations. Figure 1 shows the 5a, weakly antibonding orbital, density. Figure 2 gives the total density difference, p ( C 0 ) - p(CO+), showing a depletion of electrons near the C and 0 nuclei. Mu!liken population analyses of C O and C O + are given in Table IV. In CO+, the loss of one electron is mostly felt by the a population of the carbon (-0.85 e) and little by the a population of the oxygen (-0.15 e), which is not surprising since the 5a orbital is mainly localized on the carbon atom. However, there is a redistribution of the T population, reducing the net loss of charge of the carbon to 0.7 e, and lowering the difference of P charge between carbon and oxygen. This is consistent with an increase of the force constant in going from CO to CO+. Nickel Difluoride. Self-consistent field calculations have been performed for different angular conformations of N i F l with the N i F internuclear distance fixed at R = 3.79 au.I2The ground state was found to be a triplet and Table V gives the energy as a function of bond angle. Fitting these points by a polynomial leads to an equilibrium bond angle of 161.6’. The
3694
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Journal of the American Chemical Society
100.12
/
June 7 , 1978 Nl'+
c
_ ~ _ _ -05141
-01626
~
-10857
.
-06967 07227 -08949
= -
-I 4812 -- -14838 -3 3249 === - 3 3 6 4 2
-1 2963
.-
__
= -38619
- 4 7644
~
-25 7299
__ __
- -52725
-261153 -261185 -32.4289
~
~
_ _ . 324725
-. = 32 9628
-~ -36 8270
- -373325
---304
1811
--304
6901
Figure 3. Orbital energy levels of F-, Ni2+,and NiF2
Figure 1. Density contour of the 5a molecular orbital of CO in the xy plane. ~ . 8: denotes zero density Density range from 0.4 to 1 X 1 0-5 e / ( a ~ )Level contour.
Figure 4. Nickel difluoride total density in the xy plane. Density range from 5 to 1 x 10-4 e/(au)3.
Table IV. CO and CO+ Population Analysis for R = 2.1 32 a u a
co CO+
s population p population oncarbon oncarbon 1.876 3.619 (1.895) (3.605) 1.711 3.084 (1.870) (3.049)
s population on oxygen 3.893 (3.894) 3.956 (3.948)
CI values are in parentheses. Figure 2. Difference of total density, p[CO] - p [ C O + ] ,in the xy plane. Density range from 0.01 to -0.04 e/(au)3. Negative density denoted by ruled areas.
infrared spectra of NiF2 trapped in an Ar matrix reveals natural isotope shifts of the N i F antisymmetric stretching freq ~ e n c yFrom . ~ these shifts the bond angle was calculated as
Table V. NiF2 Energy vs. Bond Angle 0, deg
E , au
152 166 180
-1698.245 59 -1698.259 56 -1698.198 02
p population onoxygen __ 4.612 (4.607) 4.249 (4.133)
Besnainou, Whitten
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3695
Interaction between Nickel Difluoride and Carbon Monoxide
Table VI. NiF2 Population Analysis (0 = 152’)
F
Ni Is 2s 3s 4s
Total
2.000
2Px
1.997 1.992 0.118 6.107
2PY 2PZ
Total 2p 3Px 3PY
3Pz Total 3p Total p
1.949 1.949 1.949 5.847 2.052 2.050 2.05 1 6.153
3dxz 3dy2-,2 Subtotal 3dxy 3dxz 3 dyz
Subtotal Total d
1.566 1.454 3.020 1.996
S
0.939
S’
1.032 2.029
S”
Total
4.000
1.970 1.969 1.985
Px P, Pz
Total
5.924
1.030 1.999
5.025 8.045
12.000
Figure 6. Nickel difluoride a, open shell orbital. Density contour in the IOp5 e/(au)).
xy plane; density range from 0.5 to 5 X
Figure 5. Nickel difluoride a2 open shell orbital. Density contour in the e/(a~)~. Z = 1 plane; density range from 0.5 to 5 X
152O neglecting anharmonicity. If anharmonicity is taken into account, the angle is found to be in the range 157-164°,3 and thus there is good agreement between the experimental and theoretical value. The calculated minimum energy is -1698.263 30 a u showing that the NiF2 species is bound with respect to Ni2+ 2F- taken a t infinite separation. The stabilization energy is 569.7 kcal/mol which compares fairly well with the thermodynamic estimate of 655 k ~ a l / m o l . ’ ~ In Figure 3, an orbital energy diagram depicts the combination of Ni2+and F- levels to give the orbital energies of NiF2 for a linear FNiF structure. Of the two singly occupied orbitals, one is of do-po type and the other d r - a . The fluorine energy levels are lowered on approaching Ni2+ and those of the nickel levels are raised. The fluorine nickel bond acquires some covalent character and the 4s orbital of nickel, which was empty in Ni2+, now participates in the bonding. In the case of a bent configuration of Czr symmetry, the two singly occupied orbitals are now of al and a2 symmetry. Qualitatively, these can still be described as of du-pu and d a - p a type although the a1 symmetry contains some s, py, and px character. In Table VI is summarized the population analysis of bent NiF2 with 0 = 1.52O. The s plus d total population of nickel increases by an amount 0.1 52 e compared to Ni2+, equal to the p a and p r
+
electron loss of the fluorine atoms, while the p population of N i remains the same. Density contours in Figures 4-6 emphasize the quasi-linearity of the molecule (here 0 = 152’) and the nearly atomic character of the two singly occupied orbitals; 4(a2) = d, - X(pf p r ) and @(a,) = d, - X’(pr pp) where X and A’ are small. NiFZCO. Analysis of the IR spectrum of NiF2CO in an argon matrix shows that the carbonyl is bonded to the nickel atom through carbon.* NiFzCO is a planar system of CzU symmetry. In the molecule, both the NiF2 and CO stretching .frequencies are perturbed, the CO frequency increasing from 2148 to 2214 cm-I. As suggested previously by other authors,I4 it is of interest first to determine the modification of the CO bond vibration due to its incorporation into NiF2CO. We have performed an approximate vibrational analysis of NiF2CO using W i l s ~ n ’ s ’FG ~ matrix method and have calculated the change in the CO frequency by perturbation theory with a diagonal force field. Keeping the C O force constant equal to 18.55 mdyn/& and choosing the N i C force constant to have
+
+
Table VII. NiF2CO. Energy vs. Ni-C Distance R N ...c, , au
E , au
3.80
- 18 10.7484
4.25
-1 810.7528 -1810.75 11
4.48
3696
Journal ofthe American Chemical Society
100:12
1 June 7 , 1978
Table VI11. NiF2CO Mulliken Population Analysis. R N ... ;c = 4.25 au, C O Direction alongy Axis
Ni IS
2s 3s
4s Total
2.000 1.997 1.992 0.077 .6.066
2p,
2p, 2p, Subtotal 3p,
3Pv 3Pz Subtotal
F 1.949 1.949 1.949 5.847 2.052 2.052 2.051 6.155
3d,i
Subtotal 3d, 3d,,
1.585
s
1.444 3.029 1.988 1.025
3d,,
1.992
subtotal
5.005
Total
8.034
SI
S"
Total
0.939 1.032 2.028 3.999
0
C
pr pr p2 Total
1.972 1.972 1.988 5.932
s
px p,
pz Total
3.354 0.608 0.992 0.616 5.570
s
px p, pz Total.
3.950 1.402 1.722 1.392 8.466
Table IX. CO Comparative Population Analysis
s + P.
Molecule
co NiF2CO
co+ coy
on carbon
s + P. on oxygen
4.491 4.346 3.642 0.7 4.3
5.509 5.672 5.358 0.3 5.6
ii
ii
a n carbon
on oxygen
I ,004
2.996 2.794 2.691
1.224 1.153
Estimated value, derived from CO+. Table X. CO, NiF2, and NiF2CO Dipole and Quadrupole Moment
Components Relative to the Center of Mass. from SCF Calculations"
co NiF2 NiF2CO
in.
-0.256
(-0.096) +3.219 +3.716
-7.8267 (-7.5271) -16.1696 -43.9253
-10.1067 (-9.080s)
-35.1792 -32.8349
-7.8267 (-7.5271) -15.1208 -23.6806
Values are in atomic units. Results in parentheses are from ref
Figure 7. NiFzCO total dcnsity in the xy plane. Density range from 4 to
4x
10-3
q ( 4 3 .
Diffmncc of total density, p[NiF2CO] - p[NiF2], in the xy plane. Negative density denoted by white enclosed areas. Density range from 0.01 to -0.04 Figure 9.
Figure 8. NiF,CO a, open shell orbital. Density contour i n the xy plane. Density range from 0.4 to 5 X IO-'e/(au)).
the same value as in nickel carbonyl, 2.1 mdyn/A at a n internuclear distance of 1.82 ,&,I6 gives a CO frequency shift of 49 cm-I. I f k = 0.5 mdyn/,& for NiC, a value corresponding t o
a moderately strong nonbonded interaction, the CO frequency shift becomes IO cm-'; thus, the N i C force constant, reflecting the strength of the NiC bond, has a direct effect on the CO frequency shift distinct from any changes in CO bonding.
Besnainou, Whitten f Interaction between Nickel Difluoride and Carbon Monoxide
In order to investigate the bonding of CO to NiF2 and changes in the CO bond on formation of NiFzCO, S C F calculations were performed on NiF2CO employing the same basis as used for NiF2 and CO. The NiF2 bond angle and the CO internuclear distance were kept equal to 152O and 2.132 au and three different N i C distances were tried around 2 8, which is a typical value encountered for nickel carbonyls. In all cases, the complex remained in a triplet ground state. Results in Table VI1 show a slight energy minimum a t R N ~ = C 2.25 A, but the system is unbound by -0.1 a u with respect to NiF2 CO a t infinite separation. Thus, it is possible that the slight minimum is simply an artifact of the relatively small basis S C F treatment. CI would be expected to favor stabilization of the complex relative to separated NiF2 and C O , but a gain ofO.l au is not likely. It is possible, of course, that the association is due to matrix effects, and this conclusion would be consistent with the fact that the NiF2CO species has not been identified in the gas phase. In the following, we assume that the NiF2 and CO are positioned a t a N i C distance of 2.25 8,and proceed to study the effect of such an association on the electronic structure. The N i C distance of 2.25 8, is somewhat shorter than the sum of the van der Waals radius of carbon and the ionic radius of dipositive nickel ( I .65 8, 0.72 8, = 2.37 A). At this distance, inspection of the S C F orbital energy levels shows a slight shift from the corresponding levels in NiF2 and CO (increased energies for NiF2 and lower energies for CO). The closed shell orbitals retain their nickel difluoride or carbonyl character. The most prominent feature is the participation of C and 0 orbitals, mainly the C 2s, in the d,-p, open-shell orbital. Table V l l l gives a Mulliken population analysis of N i F 2 C 0 . IfwecomparetheNiFzregion t o a n isolated NiF2, we notethat the total p population remains the same, but the d population decreases by 0.01 e. The d, charge increases slightly whiled, decreases. The 4s orbital is depleted by 0.04 e while the fluorine p,p; orbitals gain 0.005 e. For the CO region, we find that it retains essentially a cylindrical symmetry: px and pz population are nearly identical. The carbon atom loses u charge but gains back more P charge; for oxygen, the reverse is observed. There is a total transfer of 0.04 e from nickel difluoride to the carbonyl. We give in Table IX a comparative analysis of the population of the CO bond in CO, NiF2CO. and CO+. Recalling the earlier discussion, in going from CO to C O + there was a redistribution of both u and P charge resulting in a net loss of 0.7 e from C and 0.3 e from 0. In NiF2C0, we find that it is possible to reproduce the r population in the CO region by adding 0.7 e on C and 0.3 e on 0 to the u population of CO+, implying that the C O bond has been modified compared to C O in a manner that qualitatively leads to its strengthening. Figure 7 shows the total electron density of the NiF2CO complex in the xy plane. Figure 8 illustrates density contours of the singly occupied orbital of a, symmetry, composed of the a l occupied orbital of NiF2 and a C O orbital of antibonding character. Figures 9 and I O refer to the total density difference between the complex and its component molecules: NiF2 for Figure 9, and CO for Figure 10. White areas correspond to negative densities and it is seen that they exist especially between carbon and oxygen, and to a lesser extent on the atoms themselves. The interatomic transfers of charge are not always reflected by Mulliken populations where negative contributions can be compensated by atomic contributions of opposite sign when density is integrated. Further evidence for a polarization of the electronic distribution of CO on formation of N i F 2 C 0 can be obtained from an analysis of the dipole moment. I n Table X, dipole and quadrupole moments of NiF2, CO, C o t , and N i F 2 C 0 are tabulated. Adding vectorially the dipole moments of CO and NiF2 gives a resultant moment of 2.96 au, differing from that of NiF2CO by 0.75 au. Transferring 0.04 e from NiF2 to CO
3697
+
+
Figure 10. Difference of total density, p[NiFzCO] - p [ C O ] .i n thc xy plane. Negative density denoted by white enclosed areas. Density range rrom 0.01LO -0.04 4 ( . 4 3 .
reduces the difference, but further changes in the polarization of NiF2 or CO are needed to account for the discrepancy. Summarizing, the C O bond is polarized by the field of the dipositive Ni, the actual transfer of charge from NiF2 to CO is small, and the combined u, P character of this donation implies very weak N i C bonding. T h e results of the energy computation directly support this contention since NiF2CO is not bound, as a free molecule, compared to NiF2 and CO. The matrix is therefore required for association of the species. The shallow energy minimum, which as noted may simply be an artifact of the present level of treatment, would lead to a force constant for the NiC bond on the order of that due to a van der Waals interaction. Thus, the effect of the N i C force constant on the perturbation of the CO frequency would be only on the order o f a few wavenumbers. Since the matrix effects are known to be small, it follows that the 70-cm-I CO frequency shift, observed experimentally on NiFzCO association in an argon matrix, is due to an electronic modification of the CO bond. As described above, both P and u polarizations occur. Similar interpretations have been proposed by other authors studying the properties of CO adsorbed on metals.'4,17.18The proposal that there could be u transfer from carbon with r back-donation from the nickelI7 is not found to apply in the NiF2CO system.
Acknowledgments. We would like to thank Mr. Le Rouzo, Mr. 0.Tapia (C. M. 0. A.),and Dr. B. Silvi (Laboratoirede Spectrochimie I. R. Paris VI) for many interesting discussions. The automatic drawing of density contours from electronic densities was made possible due to the technical assistance of Mrs. Ciorgi (C. M. 0.A,). O n e o f t h e authors (J.L.W.) would like to acknowledge helpful discussions with and the hospitality of Professor Raymond Daudel and Dr. Carl Moser during his stay in France. We are also grateful to Dr. P. G . Burton of Wollongong University for drawing our attention to this problem. References and Notes (1) (a) Centre de Mcanique Ondulatoire AppliquCe: (b) Univerrite de Paris IX.
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(2) (a) C. W. De Kock and D. A. Van Leirsburg, J. Am. Chem. SOC., 94,3235 (1972); (b) D. A. Van Leirsburg and C. W. De Kock, J. Phys. Chem., 78, 134 (1974). (3) J. W. Hastie, R. H. Hauge, and J. L. Margrave, High Temp. Sci., 3, 257 (1971). (4) G. E. Leroi, G. E. Ewing, and G. Pimentel, J. Chem. Phys., 40, 2298 (1964). (5) J. L. Whitten, J. Chem. Phys., 44, 359 (1966). (6) (a) H. M. Gladney and A. Veillard, Phys. Rev., 180,385 (1969); (b)B. Roos, A. Veillard, and G. Vinot, Theor. Chim. Acta, 20, 1 (1971). (7) H. Basch, C. J. Hornback, and J. W. Moskowitz, J. Chem. Phys., 51, 1311 (1969). (8) J. D. Petke, J. L. Whitten, and A. W. Douglas, J. Chem. Phys., 51, 256
(9) (10) (1 1) (12) (13) (14) (15) (16) (17) (18)
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(1969). J. L. Whitten and M. Hackmeyer, J. Chem. Phys., 51, 5584 (1969). B. D. Neumann and J. W. Moskowitz, J. Chem. Phys., 50, 2216 (1969). R. C. Sahni and B. C. Sawhney, Trans. Faraday SOC.,2, 64 (1968). The NiF distance corresponds to values in the perovskite structure (2.007 A) and the rutile structure, 1.98 and 2.01 A; 2.007 A = 3.79 au. L. Brewer, G. R. Somayajulu, and E. Brackett, Chem. Rev., 111 (1963). N. S. Hush and M. L. Williams, J. Mol. Spectrosc., 50, 349 (1974). E. B. Wilson, J. C. Decius, and P. C . Cross, “Molecular Vibrations”, McGraw-Hill, New York, N.Y., 1955. S. Besnainou and P. Labarbe, J. Mol. Struct., 2, 499 (1968). C. L. Angel1 and P. C. Schaffer, J. Phys. Chem., 70, 1413 (1966). G. Blyholder, J. Phys. Chem., 68, 35 (1964).
Molecular Orbitals from Group Orbitals. 6. Quantitative Evaluation and Nature of the Stabilizing and Destabilizing Orbital Interactions in Difluoroethylenes and Fluoropropenes Myung-Hwan Whangbo, David J. Mitchell, and Saul Wolfe* Contribution from the Department of Chemistry. Queen’s Uniuersity, Kingston, Ontario, Canada K7L 3N6. Received August 22, 1977
Abstract: A b initio SCF-MO calculations, with extensive geometry optimization at the STO-3G level, have been performed on the three isomeric difluoroethylenes and on the 1 - and 2-fluoropropenes. For the fluoropropenes, this basis set reproduces the principal experimental differences between the isomers, viz., ( 1 ) the relative stabilities are 2- > cis-1 > trans-1; ( 2 ) the
F-C-CH3 angle in 2-fluoropropene is significantly smaller than 120’; (3) eclipsed conformations (methyl CH eclipsed to C=C) are more stable than staggered conformations; (4) the methyl rotational barrier is lower in cis- I-fluoropropene than in trans- I-fluoropropene. For the difluoroethylenes, the STO-3G basis set incorrectly predicts the trans isomer to be more stable than the cis; however, the preferred stability of the 1 , l isomer and the small FCF angle in this compound are reproduced correctly. The results have been analyzed in terms of a recently described perturbational molecular orbital procedure which calculates orbital interactions between molecular fragments quantitatively using fragments and fragment orbitals derived from the a b initio wave functions. Two fragmentation modes have been examined: method a, in which XFC2H2 is dissected into XF and CzH2; and method b, in which XFC2H2 is dissected into X and FC2H2. Method a predicts incorrectly that the 1,)-disubstituted alkenes are much less stable than the 1,2 isomers. On the other hand, use of the FCzH2 fragment orbitals of method b leads to an internally consistent description of the stereochemical behavior of all six molecules. Only the r-type fragment orbitals are needed to achieve agreement with the various trends in the total energies. The reason for this is that only these orbitals contribute to the highest occupied molecular orbitals (HOMOS)of the various molecules and, in all cases, the stereochemical behavidr of the HOMO parallels that of the total energy. The quantitative results are supplemented by a detailed qualitative description of the nature and origin of the fragment orbitals, the relative magnitudes of the different orbital interactions, and the importance of overlap effects. This discussion includes a set of simple rules, based on second-order perturbation theory, for obtaining the orbitals, and the relative magnitudes of the atomic coefficients in these orbitals, in a general fragment C=C-
X.
One of the most useful concepts in stereochemistry is that the geometries of molecules can be rationalized in terms of a minimization of repulsive forces between bonds, between nuclei, and between lone pairs. The valence shell electron pair repulsion model (VSEPR)] is a well-known example of the successful application of this concept to geminal effects, Le., effects associated with bonds, nuclei, and lone pairs grouped about a central atom. Extensions of such thinking, from geminal effects to vicinal effects, can be found in textbooks of organic chemistry and conformational analysis. Thus, the gauche conformation of n-butane is said to be less stable than the anti conformation because of “steric repulsion between the methyl groups”;* alternatively, “. . . the instability of the gauche form of butane may be ascribed entirely to the Me-Me ir~teraction”.~ Empirical force field calculations4 treat “steric repulsion” explicitly in terms of explicit relations for nonbonded repulsive interaction energies of the van der Waals type. However, to achieve quantitative agreement with experiment, it is also necessary to include, inter alia, London attractive forces in the 0002-7863/78/ 1500-3698$01.OO/O
description of nonbonded interactions, as can be seen upon inspection of the well-known Lennard-Jones,6 and Buckingham potentials’ which are employed in force field methods. Thus, the notion that intramolecular attractive forces play a significant role in conformational analysis is as firmly established as is the concept of minimization of repulsive forces. Nevertheless, the discovery* of conformational effects, associated especially with the presence of lone electron pairs and/or polar bonds, which seem to be a t variance with the concept of minimization of repulsive forces, came as a surprise, and this “surprise” has triggered extensive discussion in recent years into the nature and the magnitude of intramolecular attraction. Unfortunately, the force field method cannot yet be applied reliably to this problem, because of a lack of suitable potential functions for nonhydrocarbon m o l e ~ u l e swith , ~ the result that progress in the qualitative understanding of attractive effects has been achieved principally by the application of molecular orbital and, especially, perturbational molecular orbital (PMO)Io methods. 0 1978 American Chemical Society